Direct-current restorer system for compensating for the finite impedance of restoring tubes



2 sneaks-snee*u 1 LIl KIRKNESS o obl..

Aprll 13, 1954 R DIRECT-CURRENT REsToRER SYSTEM FOR CoMPENsATING FOR THE FINITE IMPEDANCE 0E REsToRTNG TUBES Filed July 18, 195o Lul IGZ-N- IZOmIuZrmo OZDOw INVENmR. ROBERT H. KIRKNl-:ss 1% ATTORNEY April 13, 1954 Filed July 1 Q R. H. KIRKNESS DIRECT-CURRENT RESTORER SYSTEM FOR COMPENSATING FOR THE FINITE IMPEDANCE OF RESTORING TUBES 1950 2 SheeLs-Shee?I 2 Time- ROBERT H. KIRKNESS ATTORNEY peaks to a reference level.

Patented Apr. 13, 1954 DIRECT-CURRENT RESTORER SYSTEM FOR COMPENSATING FOR THE FINITE IM- PEDANCE OF RESTORING TUBES Robert Hylton Kirkness, Wembley, England, as-

signor to Hazeltine Research, Inc., Chicago, Ill., a corporation of Illinois Application July 18, 1950, Serial No. 174,509

Claims priority, application Great Britain July 22, 1949 8 Claims.

GENERAL This invention relates to automatic control systems and, more particularly, to systems which autornatically control. an operating characteristic oi a signal-translating channel to compensate for any undesired variations in the operating characteristic caused by variations in characteristics of the signals applied to the system. Such a control system has particular utility in a television receiver as a direct-current restorer system for compensating for variations in the level of the restored direct-current component of the television signal caused by the finite impedance of the restoring tube and for that reason will be described in that environment.

Conventionally, there is applied to and translated through a video-frequency amplifier of a television receiver a signal having video-frequency components and synchronizing-signal components. It is customary to use alternatingcurrent coupling between the stages of such an amplier. As a result the potential on the control electrode of the succeeding tube, corresponding to a reference level for the signal, normally uctuates as a result of any variations in the video component of the applied signal. In order to eect restoration of the direct-current component of' the video-frequency signal in the input circuit of the succeeding amplier stage, a directcurrent restoration circuit or clamping device is` provided. Some circuits of this type are arranged to restore such component -of an applied signal in relation to the peak amplitudes of the line-synchronizing pulses by, in effect, clamping these Such reference level then provides the direct-current component and is related to the average background illumination of the image being reproduced.

The clamping or rectifier circuit usually comprises essentially a rectifier device coupled across a grid-leak resistor in the input circuit of the ampliiier tube in the stage utilizing such restoration in. such a sense that the rectifier only conducts when line-synchronizing or held-synchronizing pulses are applied thereto. As variations in the amount of current flowing through the rectllier occur with changes in the intensity of the applied video-frequency signals including the synchronizing-signal components, the reference potential applied to the associated amplier tube also changes in such a manner as to produce an eect which is continuously proportional to the peak intensity and duration of the applied signal. Such potential maybe representative of theaverage background illumination of the image being reproduced and any spurious variations therein may cause a change in the value of such background illumination. Due to the inherent finite resistance of the rectifier device used for directcurrent restoration purposes and other nite resistances such as that of the signal source, as the level of the applied signal varies there is also a change in the voltage developed across the rectifier as it conducts and this change or spurious variation reflects itself as an undesirable change in the reference potential and thus in the value of the background illumination.

In addition to the above-mentioned undesirable characteristic of conventional direct-current restoration circuits, such circuits also react to changes in the duration of the applied synchronizing pulses undesirably to vary the level of the restored direct-current component. Since the value of the unidirectional signal representative of the background illumination is dependent on the average current owing through the rectier circuit, the level at which short-duration or linefrequency pulses are stabilized differs from that at which long-duration or eld-ireoueney pulses are stabilized. The eld-frequency pulses being of longer duration cause current to flow through the rectifier for a longer period of time causing the reference potential to rise and, therefore, for the level of the restored direct-current component to rise during this period. Such a rise produces a change in the value of the average background illumination and is, therefore, undesirable.

It is an object of the present invention to provide a new and improved automatic control system which avoids one or more of the above-mentioned limitations of prior systems.

lt is another object of the present invention to provide for use in a television receiver a new and improved automatic control system which includes a direct-current reinsertion network and which avoids one or more of the above-mentioned limitations of prior such systems.

It is still another object of the invention to provide for use in a television receiver a new and improved automatic control system which includes a direct-current reinsertion network in which the direct-current reference level provided by the network is precisely stabilized. n

It is an additional object of the invention to provide for use in a television receiver a new and improved automatic control system which includes a direct-current reinsertion network which is substantially unresponsive to variations in signal amplitude or in the pulse duration of the recurrent svnchronizing pulses.

In accordance with the present invention there is provided a system for automatically controlling an operating characteristic of a signaltranslating channel for translating a televisionv having a iinite conduction resistance and an impedance circuit coupled to the aforesaid channel and to the amplifier, the impedance circuit having a time constant substantially longer than `the aforesaid period of the synchronizing-signal components and the device being so Vpoled. with respectv to -they aforementioned predetermined polarity thatthe restorer system is effective to derive from the television signal a control po- ,tential for the amplifier which is representative of the. predetermined shade level undesirably mod-ined by the effect of the iinite resistance ci the device. IThe system also comprises an impedance network coupled in circuit with the restorer system and including at least a portion of vthe cathodeload circuit and having a time constant substantiallyv shorter than the aforesaid time constant of said impedance circuit for developing from the television signal across the aforementioned portion of thecath'ode circuit a voltage substantially equal to the aforesaid modification of the developed potential caused bythe finite resistance of the device and means for combining the. aforesaid voltage and potential to produce a resultant potential in which the influence of the finite resistance of the rectier `device on the operating characteristic is reduced. For a better .understanding of the present invention, together with other and further objects thereof, reference is hadto the following description taken `in connection with the accompanyingl drawings, and its scope will he pointed out in the appended claims. Y

Inthe accompanying drawings, Figi 4is a. circuit diagram,V partly schematic, of a television receiver including Aanautcmatic control system embodying a particular form of the present invention: FigsjZa-ZC, inclusive, are graphs useful in explaining the operation of the automatic control system utilized inthe Fig. 1 receiver; Figs. 3 and l represent modified forms of the automatic control system of Fig. l; and Figs. Srl-5c, inclusive, are graphs useful in explaining lthe operation of the system of Fig. 4.

- General description of receiver of Fig.V 1

VReferring now more particularly to Fig. 1 of the drawings, there is represented therein a television receiver including a signal-translating Y channel comprising an automatic control system 4 automatic-gain-control (AGC) supply I5, a signal-translating channel I6 being more particularly a video-requency amplifier of one or more alternating-current coupled stages, and an image-reproducing device IB. The channel it includes an automatic control system embodying the present invention in one form to be more particularly described hereinafter. There is also coupled to the detector I5 a synchronizing-signal separator IS having output circuits connected with a line-frequency generator itil and a neidfrequency generator 2l. rThe output circuits of these generators, in turn, are connected with beam-deflecting windings in the image-repro'- ducing device I8. The output circuit of the automatic-gain-control supply of unit i5 is connected to the'input circuits of one or more of the tubes of radio-frequency amplier iE, oscillatormodulator I3 and intermediate-frequency ampliner I4 in Well-known manner.

A sound-signal reproducer 22 is also connected to the output circuitfof the amplifier irl. The

`reproducer 22 may have stages of intermediatefrequency amplification, a sound-signal detector, stages of audio-frequency amplification and a vsound-reproducing device.

It will be understood that the various units thus far described, with the exception of portions Vof the signal-translating channel Iii, may have any conventional.construction and design. The details of such components are well known in the art rendering a further description thereof Y unnecessary.

General explanation of the operation of rcceicer of Fig. 1

Considering briefly the operation of the receiver as a whole and assuming for the moment that the unit I6 is a conventional video-frequency ampliiier, a desired modulated television wave signal is intercepted by the antenna system II, il. The signal is selected and ampliiied in the radio-frequency amplier l2, applied to the oscillator-modulator I3 wherein it is con- -verted into an intermediate-frequency signal,

latter being translated through the amplifier Hi and havingV the modulation-signal components The derived components, which comprise video-frequency as well as recurring or synchronizing-signal coinponents, are amplied and translate-d through vthe video-frequency amplifier iii, wherein the direct-current component of the video-frequency 4signal is restored, and appliedrto the lorilliancycontrol electrode of the image-reproducing device I 8 to modulate the intensity of the electron beam vtherein in accordance with the variations in intensity of the video-frequency components. The synchronizing-signal components of the received signals are separated from the video-frequency components in the separator i9 and are used to synchronize the line-frequency anclfield-irequency generators 2i! and 2|, respectively. These generators then apply signals of 'saw-tooth. wave form properly synchronized with reference the'received television signal to the beam-deflecting windings of the image-reproducing de- .vice I8 thereby to deect the reproducing seam therein in two directions normal to each other to reproduce the received television image.

. The automatic-gain-control or (AGC) signal derived in the unit I5 is effective to control 'the amplification of one or more of the units ifi, i3 and I4 to maintain the signal input to the tector I5 and to the reproduoer 22 Within a relatively narrow range vfor ay wide range of the received signal intensity.

The sound-signal modulated wave signal is also intercepted by the antenna system II, II and after selective amplification in the ampliner I2 is converted to a sound-modulated intermediate-frequency signal in the oscillator-modulator I3, the latter being translated through the amplifier I4 and applied to the reproducer 22. In the reproducer 22 this signal is amplified and detected to derive the sound-signal modulation components which may then be further amplified and utilized therein.

Description of automatic control system of Fig. 1

Referring now more particularly to the automatic control system of Fig. 1 which comprises a black-level stabilization network I'I coupled in the input circuit of the second of two resistorcondenser coupled amplifier stages, one including an amplifier IBa and the other including the tube 25, respectively. The amplifier Ia represented in block form may be of conventional form for the amplification of video-frequency signals, particularly it may comprise a pentodetype amplier. rlhe amplier stage is a videofrequency amplifier including the vacuum tube 25 and has an input circuit coupled to the output circuit of the amplifier Ita through a coupling condenser 23. Biasing means coupled to the control electrode of the tube 2-5 comprises the condenser 23 and a grid-leak resistor 26a. The end of the resistor 26a remote from the condenser 23 is coupled to a source of bias potential -C1 through a resistor 2Gb. The anode of the tube 25 is coupled to a source of suitable +B potential and the cathode is coupled to ground through series-connected cathode load resistors 21a and 2lb, the resistor 2lb being a L components having pulses of positive polarity and of distinctive durations and different periods and may include the system I1 for automatically controlling an operating characteristic, specifically for controlling the black level or stabilization of a signal in a signal-translating channel in accordance with the present invention. The system I1 comprises a direct-current restorer system including a rectier device having a finite conduction resistance and comprising the diode 24 and including an impedance circuit coupled to the aforesaid channel and to the amplier, speciiically, the series circuit of the coupling condenser 23, and a pair of resistors 26a and 26h coupled between the amplier Ita and a source of potential 01. The resistor 26a is connected between the cathode and anode of the diode 24, the cathode also being connected to the control electrode of the tube 25. The impedance circuit, specifically the circuits of the condenser' 23 and the resistors 25a and 23h, has a time constant substantially longer than the period of the line-frequency synchronizing-signal components and the device including the diode `24 is so poled with respect to the predetermined polarity of the synchronizing-signal peaks that the restorer system is effective to derive from the television signal a control potential for the control electrode of the tube 25 which is representative of the black level undesirably modilied by the nite resistance of the diode.24.l

The automatic control system 'I 'I also comprises an impedance network coupled in circuit with the rectifier system, in particular in series with at least a component, specically a rectifier device or tube, of the rectifier system, and which includes at least a portion of the cathode load circuit of the ampliiier. The network is so proportioned as to develop from the television signal a second control effect or potential related to voltage variation across the rectifier device.

As will be explained hereinafter, there is developed across the rectifier device 2e when conductive a voltage varying with a characteristic of the television signal and undesirably affecting the operating characteristic or black level of the signal. More particularly, the voltage developed thereacross, and thus across the resistor 2te, varies with both the average amplitude of the television signal and with differences in the pulse durations of the synchronizing-signal components. Specifically, the impedance network is a time-constant network comprising a condenser 29, coupled between the anode of the rectifier' device 24 and ground, and a resistor 30 effectively coupled in parallel therewith through a portion of the voltage divider 2lb. The time constant of such network is substantially shorter than the time constant of the aforesaid circuit including the condenser 23 and the resistor 26a and is effective to develop from the television signal across the aforementioned portion of the cathode circuit a voltage substantially equal to the aforesaid modication of the developed potential caused by the iinite resistance of the device. The impedance network may also comprise the cathode load circuit of the tube 25 including both the resistors 21a and 2lb. The proportioning of the impedance network is effected by proper determination of the values of the condenser 2li and the resistors 30, 21a and 2lb to develop a value of the second control effect across the condenser 2S which is proportional and has an opposing sense to the voltage variation across the diode 24. Preferably, the resistor 2lb has a value which comprises approximately 10% of the total load of the resistors 21a and 21h. Also, the time constant of the circuit essentially including the resistor 3! and the condenser 29 is proportioned to be small with relation to that of the grid-biasing network including the con denser 23 and the resistor 26a. In addition, the coupling of the resistor 30 to the resistor 2lb is preferably adjustable to eiect the desired potential across the condenser 29, as will be explained more fully hereinafter.

The system I'I also comprises means for com.- bining the aforesaid voltage and potential or the potentials developed across the diode 2li and across the condenser 29 to produce a resultant potential or potential in which the deleterious influence of the finite resistance of the rectiiier device across the diode 24, while conducting, on the operating characteristic or black level oi the television signal is reduced or preferably canceled. This means comprises the leads connecting the network including the condenser 2&3 and resistor 30 effectively in series with the resistor 25a so that the potentials developed across the resistor 26a and across the combination of the condenser 29 and the resistors 30 and 2lb combine to provide the biasing potential for the control electrode of the tube 25.

There is also included in the video-frequency amplifier I6 output4 terminals 23,28 for coupling' the signal developed .in .the .cathode .load resistance of-the tube 25l'to: the input. circuit of the image-reproducing device `I8.

Explanation ofV the operation of the automatic control system of Fig. 1

The amplifier 16a and the vacuum tube t5 operate in a conventional manner to amplify and translate the'video-frequency signals from the output of the detector iii to the input circuit of the image-reproducing device I8. The auto-- matic control system l1 operates in a manner toV maintain the black level ofthe television signal being translated through the above-mentioned amplifier stages stable i. e. substantially indeH pendent of video-frequency signal variations. This stability is maintained even though the average-amplitude level of the signal being trans lated through the circuit may vary. The 1nan ner in which the system li operates to eiiect such stability and the problem created by the YVariationin average amplitude of the television signal may best be understood by reference to 'the curves oi Figs. 2er-2c, inclusive.

Fig. 2a represents a television signal having diiierent levels that might be translated thro gli the amplifier I6, speciiically representing a nal that might be applied to the control electrode oi" the tube 25 ignoring for the purpose-oi this consideration the eiect of the condenser 23 in causing the signal to have an alternating-current axis at this point. In Fig. 2a and iigures referred' to hereinafter, the lette-rs E and W respectively represent the synchronizing, black and white levels of the television signal. Also, no reference axes have been shoe/n the curves of such figures, since such ages not essential to the explanation oi the invent-,ic z it is to be understood that all signals Conventionally, in modern ltelevision receivers,

the rectier 2li of the direct-current reinserter system conducts on synchronizing-signal peaks for the purpose of re-establishing in the receiver a black level for the television signal. Due to the finite resistance of a rectifier such as the diode 2Q and other nite resistances in the circuit supplying the signal, there is 'a potential .developed across the tube 24 while it is conducting depending upon the magnitude of the current flowing through the tube. Thus, in the presence of a pure black signal, when only a small amount of current flows through the diode 2li, a potential drop of one value is established thereaoross. In the presence of pure white signals, when more current is iiowing therethrough, a diiierent potential is developed thereacross. This variation in potential across the diode 2s causes the synchronizing and black levels of the signal to become unstable as represented by the curve of Fig. 2b. Effectively, due to the described variations in the potential across the diode Eil, the average background illuminationY of the image being reproduced by device I3 undesirably varies as the average intensity of v.the signal being translated throughithe tube'25I varies. The im# 8 pedance :network including the condenser.4 23an`d the resistors 38 and 2lb is proportioned jtocom'- pensate for this undesired variation in potential drop in the diode 24. The curve rof Fig. 2c represents the variation in potential across kthe condenser 29 with variations inthe average amplitude of the television signal.

The voltage developed across the condenser 29 is proportional to the current nowing through the tube 25, therefore, to the potential of the signal applied to that tube. More specically, the voltage across the condenser 29 is related to the potential developed across the resistor 2lb. The resistor 30 and the condenser 29 provide a 'f 'time-constant network for developing, across the condenser 29, the voltage across the lower part of the resistor 2lb then connected to the condenser 29 through the resistor Sii. The reaction of the network 29, 30 is in the proper sense to compensate for a similar reaction of the nite impedance of the signal sourceia, the condenser 23 and the diode 24 and is represented in the curve of Fig. 2c by the rise in potential indicated between the times to and ti. `Also, as the level of the potential across the condenser 2t buildsup to that representedby the portion oi the curve of Fig. 2c between the times t1 and tz, this potential is in the proper sense and of the proper amount to loffset the undesired drop in potential across the diode 2d occurring during conduction therein and, therefore, the undesired variation across the resistor 2da, at the saine time, in the manner previously described. .it is thusrseen that by, properly proportioning the values of the resistors 2'ia, 2lb and and the condenser 29, a potential may be developed across the condenser 29 from the television signal which willbe related to the undesired voltage variation occurring across the diode 24 during conduction as the average amplitude level of the television signal changes. Therefore, as the reference potential across the resistor 25a tends to drop under such conditions, such tendency is oiiset by theopposing tendency of the potential across the condenser 29.

'From the above discussion it will also be seen that as the level of the television signal changes from white to black at the time t2, the ecay in potential across `'the condenser 29 between the 'times t2 and t3 is' of such a value and in suoli a sense as to odset the change in potential then occurring across the resistor 23a due to the finite resistance of the diode 2t andV of the signal source.

Description and explanation of operation of the automatic control system in the embodiment o! rias Referring now to Fig. 3, there is represented therein a modified form of vided-frequency am plier I6. Since the ampliers of Fig. l Fig.

3 are similar to each other, similar components are designated by the same reference numerals and analogous components by the same refern ence numerals primed. i' Y rIhe only difference between the amplier of Fig. 3 and that of Fig. Il is the utilization ci the vacuum tube 25' therein as an vamplifier tube rather than as simply a cathode-follower stage as in Fig. 1. For the purpose of obtaining such amplification, there is included in the anode circuit of the tube 25' an anode load resistor iii which is coupled to a source of potential +B and comprises the output circuit 4'of the tube 255 sing coupled 'toa terminal 2.8..`

59 f It will be seen that the operation of the automatic control system in the embodiment of Fig. 3 is similar to that of Fig. 1. The operation of the tube 25 as an amplier is conventional and requires no detailed explanation.`

Description of automatic control system embodied in Fig. 4

Fig. 4 represents a video-frequency amplifier including a modiiied form of the automatic control system according to the present invention. Since many of the components of the amplifier of Fig. e are similar to those in the video-frequency amplifier of Fig. 1, similar components are designated by the same reference numerals and analogous components by the ysance reference numerals double primed.

In addition to the components described with reference to the system l1 of Fig. 1, there is included in the system Il of Fig. 4 a second network coupled in circuit with the rectiner system and so proportioned as to develop from the television signal an additional control effect or third potential related to the undesired variation in the potential developed across the diode 24 produced by differences in the pulse durations oi the synchronizing-signal components applied to the input circuit of the tube 25. More particularly, the second network is proportioned to develop a potential which compensates for the variations in the bias potential related to the black level and which are produced by the differences irl pulse durations between line and field pulses. The second network includes a series-connected diode 32 and a resistor 3l coupled between the cathode of the tube 25 and the anode of the diode 24. The second network also includes a voltage divider resistor 33 coupled between a source of potential, indicated as --Cz and ground and adjustably connected through a high value resistor 39 to the cathode of the diode 32.

The values of the resistors 3|, 21a, 2lb and 3i)` in the control system Il of Fig. 4 are proportioned to eiect results described more fully hereinafter when explaining the operation of the system. Such proportioning is well known to those skilled in the art and is best described in terms of the effects which are sought. More specifically, the resistor 3| is proportioned to have a value less than that of the resistor 3U while the cathode of the diode 32 is connected to a point on the resistor 33, through the resistor 39, so that a potential is developed at the cathode thereof which causes it to be more negative than the anode thereof when no current is flowing in the tube 25.

Explanation of the operation of automatic control system of Fig. 4

The explanation of the operation of the system il" of Fig. 4 is best understood by reference to Figs. oit-5c, inclusive. The curve of Fig. 5a

represents a continuous white signal in which` than it conducts in the presence ot short-duration, line-frequency pulses, there is a tendency for the potential representing the black level of the signal and which is developed across the resistor 26a to rise eiecting a result such as is represented by the curve of Fig. 5b. It is there seen that as the bias potential rises, t-he reference levels of the television signal which are necessary to effect a proper average background illumination in the reproduced image also change, undesirably aiecting the reproduction of the image. l'he second network including the diode the resistor 3l and the resistors 33 and 39 reacts to the synchronizing pulses Vin suc-li a manner as to olset this tendency or the reierence potential to rise in the presence oi" the longer duration pulses. 'lhe voltage developed in this network for combining with the potential developed across "the resistor Zta as the pulseduration o1' the synchronizing pulses changes is represented by the curve of 5c. rlhis curve represents the change in potential produced across the condenser 2e as line-Irequency pulses and neidirequency pulses are appiied to the diode Z4.

As has been stated when describing the networi: including the diode s2, the potential appiied to the cathode tileleoli, when no current Ilows in the tube 2e, is such as to cause tne diode 32 to conduct thereby at least partially discharging the condenser Such action occurswnen the synchronizing pulses are appiied to the control (1l-Hindi' Z5 during line P61100. OI H16 .long-Llul'ablon 'leiu-Synlll'OIllZiIlg palmes 1S SLAIDCLEIIB DO QLLSBU the rise in potential across the diode 214 duringA the same pei-lod. in this way, it is possioie to maintain the level oi the reierence potential sup-` plied tothe control electrode of the tube ze constant under conditions of both variations in the average signal intensity or the applied signal and dinerences in the pulse dui-ations or the synchronizing-signal pulses.

While there have been described what are at present considered to be the preierred embodiments or' this invention, it will be obvious to those skilled in the art that various changes and moui- Iications may be made therein without departing" from the invention, and it is, thereore, aimed to cover all such changes and modifications as.

fall within the true spirit and scope of the invention.

What is claimed is:

1. A system for' automatically controlling an operating characteristic of a signal-translating channel which translates aftelevision signal having vdeo-frequency and synchronizing-signal components of a predetermined polarity period and having a predetermined shade level comprsing: a video-frequency amplier coupled to said channel for translating at least said video` frequency components and including a cathode# load output circuit for said translated compo-A nents; a direct-current restorer system including a rectiner device having nite conduction resistance and an impedance circuit coupled to' said channel and to sadampliner, said impedance circuit having a timeconstant substantially Vill longer than said period of said synchronizingsignal components and said device being so poledl with'respect to said predetermined polarity that said restorer system is effective to derive from said television signal a control potential for said amplifier which is representative of said predetermined shade level undesirably modied by said iinite resistance of said device; an impedance network coupled in circuit with said restorer system and including at least a portion of said cathode load circuit and having a time constant substantially Vshorter than said time constant of said impedance circuit for developing from said signal across said portion'of said load circuit a voltage substantially equal to said modication of said potential caused by said finite resistance of said device; and means for combining said voltage and said potential to produce a resultant potential inA which the influence of said nite resistance of said device on said operating characteristic-is-reduoed.

2. A -system for Iautomatically controlling the black level of a signal in a signal-translating channel which translates a television signal having video-frequency and synchronizing-signal components of a predetermined polarity period and having ablaclc level comprising: a videofrequency amplifier -coupled to said channel for translating at least said video-frequency components and including a cathode-load output circuit Afor said `translated components; a directcurrent-restorer system including a rectiiier device hav-ing finite lconduction resistance and an impedancev circuit-coupled to said channel and to said amplifier, saidv impedance circuit having a time constant substantially longer than said period :of -said synchronizing-signal components andsaid device being so poled with respect to said predetermined polarity that said restorei` system is effective to derive from said television signal acontrol potential 4for said amplifier which is representative of said black level undesirably.

modiiied by said finite resistance of said device; an impedance network coupled in circuit with said restorer system and including at least a portion of said cathode load circuit and having a time.k constant substantially shorter than said time constant of said impedance circuit for developing from said; signal across said portion of said load circuit a voltage substantially equal to said modication of said potential caused by said finite resistance of said device; and means for combining said voltage and said potential to produce a resultant potential in which the influence of said finite resistance of said device on said black level is reduced.

3. A system for automatically controlling the blackrlevel of a signal in a signal-translating channel which translates a television signal having video-frequency and synchronizing-signal components of a predetermined polarity period and having a black level comprising: a videofrequency amplier coupled to said channel forV level comprising:

signal a control potential for said amplifier which is representative of said black level undesirably modiiied by said iinite resistance of said device; an impedance network Vcoupled in series with at least an element of said restorer system and in` cluding at least a portion of said cathode load circuit and having a time constant substantially shorter than said time constant of said impedance circuit for developing from said signal across said portion of said load circuit a voltage sub-iA stantially equal to said modification of said potential caused by said nite resistance of said device; and means for combining said voltage and said potential to produce a resultant potential in which the influence of said iinite resistance of said device on said operating characteristic is reduced.

4. A system for automatically controlling the black level of a signal in a signal-translatingV channel which translates a television signal including video-frequency components and synchronizing-signal components having pulses of a predetermined polarity and of different durations and different periods and having a black a video-frequency amplier coupled to said channel for translating at least said video-frequency components and including a cathode-load output circuit for said translated components; a direct-current restorer system including a rectifier device having iinite conduc- Vtion resistance and an impedance circuit coupled to said channel and to said amplifier, said impedance circuit having a time constant substantially longer than the shortest one Vof said periods of said synchronizing-signal components and said device being so poled with respect to said predetermined polarity that said restorer system is effective to derive from said television signal a control potential for said amplifier whichy is representative of said black level undesirably Vmodified due to said finite resistance of said device by variations in both the average amplitude of said signal and in the pulse durations of said synchronizing components; an impedance netf work coupled in circuit with said restorer system and including at least a portion of said cathode load circuit and having a time constant substantially shorter than said time constant of said impedance circuitfor developing from said signal across said portion of said load circuit a voltage substantially equal to said modification of said potential caused by said iinite resistance of said device; and means for combining said voltage and `said potential to produce a resultant potential in which the influence of said finite resistance of said device on said operating characteristic. is reduced.

5. A system for automatically controlling the black level of a ksignal in a signal-translating channel including alternating-current coupled repeater stages which translate a television signal including video-frequency components and synchronizing-signal components having pulses of a predetermined polarity and of different durations and diierent periods and having a blackV level comprising: a video-frequency amplier coupled to said channel for translating at least said video-frequency componentsI and including a cathode-load output circuitfor said translated components; a direct-current restorer system including a rectifier device having finite conduction resistance and an impedance circuit coupled to said channel and to said amplier, said impedance circuit havingY a time constant substantially longer than the shortest one of said' 1,3... periods" of 'said 'I synchronizingsignal components and said device being so poled with respect to saidpredetermined polarity that said restorer system is effective to derive from said television signal a control potential for said amplifier which is representative of said black level undesirably modiiied due to said finite resistance of said device by variations in both the average amplitude of said signal and in the pulse durations of said synchronizing components; a first network coupled in circuit with said restorer system and including at least a portion or" said cathode load circuit and having a time constant substantially shorter than said timeconstant of said impedance circuit for developing from said signal across said portion of said cathode circuit av first voltage substantially equal to said modication of said potential caused by variations in the average amplitude of the signal applied thereto; a second network coupled in circuitl with said rectier system and having a time constant substantially shorter than said time constant of said impedance circuit for developing from said signal a second voltage substantially equal to said modication of said potential caused by said differences in said pulse durations; and means for combining said potential and said rst and said second voltages to produce a resultant biasing potential for said amplifier inwhich the influence of said finite resistance of said device on said black level is substantiallsr reduced.

6. A system for automatically controlling the black level of a signal in a signal-translating channel including alternating-current coupled amplifier stages which translate a television signal including video-frequency components and synchronizing-signal components having pulses of a predetermined polarity and of different durations and different periods and having a black level comprising: a video-frequency amplifier coupled to said channel for translating at least said video-frequency components and including a cathode-load output circuit for said translated components; a direct-current restorer system including a rectier device having finite conduction resistance and an impedance circuit coupled to said channel and to said amplifier, said impedance circuit having a time constant substantiaily longer than the shortest one of said periods of said synchronizing-signal components and said device being so poled with respect to said predetermined polarity that said restorer system is effective to derive from said television signal a control potential for said amplifier which is representative of said black level undesirably modified due to said finite resistance of said device by variations in both the average amplitude of said signal and in the pulse durations of said synchronizing components; a first network coupled in circuit with said restorer system and including at least a portion of said cathode load circuit and having a time constant substantially shorter than said time constant of said impedance circuit for developing from said signal across said portion of said cathode circuit a rst voltage substantially equal to said modification of said potential caused by variations in the average amplitude of the signal applied thereto; a second network including a second rectifier device conductive at the same time as said rst rectifier device, coupled in circuit with said rectiiier system and having a time constant substantially shorter than said time constant of said impedance circuit for developing from said signal a second voltage substantially equal to said modication of said potential caused by said differences in said pulse durations; and means for combining said potential and said first and said second voltages to produce a resultant biasing potential for said amplifier in which the influence of said unite resistance of said device on said black level is substantially reduced.

7. A system for automatically controlling the black level of a signal in a signal-translating channel which translates a television signal having video-frequency and synchronizing-signal components of a predetermined polarity and period and having a black level comprising: a video-frequency ampliiier having a control electrode coupled to Vsaid channel for translating said video-frequency components and including a cathode-load output circuit for said translated components; a direct-current restorer system including a rectifier device having finite conduction resistance and an impedance circuit coupled to said channel and to said control electrode of said amplifier, said impedance circuit having a time constant substantially longer than said first period of said synchronizing-signal components and said device being so poled with respect to said predetermined polarity that said restorer system is effective to derive from said television signal a control potential for said amplier which is representative of said black level undesirably modified by said finite resistance of said device; and a resistor-condenser network connected in series between said rectifier device and at least a portion of said cathode circuit and having a time constant substantially shorter than said time constant of said impedance circuit for developing from said signal across said portion of said load circuit a voltage substantially equal to said modification of said potential caused by said finite resistance of said device; whereby said voltage and said potential combine to produce a resultant potential in which the influence of said finite resistance of said device on said operating characteristic is reduced.

8. A system for automatically controlling the black level of a signal in a signal-translating channel including alternating-current coupled amplier stages which translate a television signal including video-frequency components and synchronizing-signal components having pulses of a predetermined polarity and of distinctive durations and diierent periods and having a black level comprising: a video-frequency amplifier including a control electrode and cathodeload output circuit for said translated components; a direct-current restorer system including a rectier device having finite conduction resistance and an impedance circuit coupled to said channel and to said control electrode of said amplifier, said impedance circuit having a time constant substantially longer than the shortest one of said periods of said synchronizing-signal components and said device being so poled with respect to said predetermined polarity that said restorer system is effective to derive from said television signal a control potential for said amplifier which is representative of said black level undesirably modified due to said finite resistance of said device by variations in both the average amplitude of said signal and in the pulse durations of said synchronizing components; a first resistor-condenser network connected in series between said rectifier device and said cathode circuit and having a time constant substantially shorter than said time constant of said impedance circuit for developing from said signal across cinemas said 'portion voi' said lcathode circuit a first v'olt-. age substantiallyV equal to said modiiication of said potential caused by variations in the average amplitude of said signal; a second network including another rectifier device coupled between said cathode circuit and said irst rectifier device and having a time constant substantially shorter than said time constant of said impedance Vcircuit for developing from said signal a second Voltage substantially equal to said modification of said potential caused by sad differences in said pulse durations; and means for combining said potential and said rst and said second voltages to produce a resultant biasing potential for said stage in which the influence of said iinite resistance of said device on said black level is substantially reduced.

1'6 f v.References Cited, in the iile of this .patent UNITED STATES PATENTS Number Name Date 2,227,056 Blumlein et al e Dec. 31, 1940 2,240,600 Applegarth May 6, 1941 2,302,425 Deerhake Nov. 17, 1942 2,515,763 Downie July 18, 1950 2,525,103 Sprecher Oct. 10, 1950 FOREIGN PATENTS Number, Y Country Y Date 474,266 Great Britain Oct. 28, 1937 OTHER REFERENCES Journal of the Television Society, London, vol. 5, #12, December 1949, pages 339-348. 

